Rolling bearing

ABSTRACT

The rolling bearing apparatus of the present invention comprises a rolling element, a non-rolling element disposed concentrically with the rolling element, and a rotation detector for outputting an input exciting voltage by converting it to an induced voltage according to the relative rotation state of the rolling element and the non-rolling element. The rotation detector comprises a rotor provided in the rolling element, a stator provided in the non-rolling element, and an exciting winding and output windings being wound to the stator. The output windings induce a voltage according to the gap permeance between the rotor and the stator in response to the exciting voltage inputted to the exciting winding.

TECHNICAL FIELD

The present invention relates to a rolling bearing apparatus and, more particularly, to a rolling bearing apparatus to which a rotation detector is mounted.

BACKGROUND ART

Conventionally, there are rolling bearing apparatuses to which a rotation detector is installed. There are a passive type and an active type in such rotation detector. The active type can detect a non-rolling state, thereby achieving rotation detection with high precision. The active-type rotation detector includes a pulser ring and a magnetic sensor. The pulser ring is made of a multipolar magnet in which the north pole and the south pole are alternately disposed in a circumferential direction and mounted on the rolling element side out of the inner ring and the outer ring of the rolling bearing. The magnetic sensor is mounted on the non-rolling element side of the rolling bearing opposing the pulser ring. As for the operation, pulse signals are to be outputted from the magnetic sensor according to the rotation of the pulser ring which synchronously rotates with the rolling element and the rotation state of the rolling element is detected by processing the pulse signals. In order to further improve the accuracy of the rotation detection in such active-type rotation detector, it is proposed to reduce each pitch of the magnetic poles of the pulser ring. However, there is a limit in reducing the pitch, which results in limiting the improvement in the accuracy of the rotation detection.

DISCLOSURE OF THE INVENTION

A rolling bearing apparatus of the present invention comprises a rolling element, a non-rolling element disposed concentrically with the rolling element, and a rotation detector for outputting an input exciting voltage by converting it to an induced voltage according to the relative rotation state of the rolling element and the non-rolling element.

Preferably, the rotation detector comprises a rotor provided in the rolling element, a stator provided in said non-rolling element, and an exciting winding and output windings being wound to the stator. The output windings induce a voltage according to a gap permeance between the rotor and the stator in response to the exciting voltage inputted to the exciting winding.

Preferably, the stator comprises a plurality of polar teeth provided in the surface of the non-rolling element opposing the rolling element, and the exciting winding and the output windings are provided by being wound to each polar tooth of the stator. Further, the rotor comprises a flat portion formed on a circumference of the surface in the rolling element which opposes the plurality of polar teeth provided in the non-rolling element.

Preferably, the rolling element is an inner ring, the rotor is formed by an outer peripheral shoulder of the inner ring, and a flat portion is formed on the circumference of the outer peripheral shoulder.

With the present invention, the non-rotation state of the rolling element can be successfully detected and also the rotation state of the rolling element can be detected in detail with high accuracy since the induced voltage is outputted in which amplitudes change with no phase according to the rotation state of the rolling element.

The above-described tolling element comprises members which rotate by being disposed concentrically with the non-rolling element, e.g., the inner ring, a hub wheel, a nut. Especially, when the non-rolling element is the outer ring, the rolling element comprises the inner ring, the hub wheel, the nut and the like as the members which are disposed in the inward-radial direction with respect to the outer ring.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view showing a rolling bearing apparatus according to a preferred embodiment of the present invention;

FIG. 2 is a side view of the rolling bearing apparatus shown in FIG. 1 as viewed from a brushless resolver side;

FIG. 3 is a schematic illustration showing a configuration of the brushless resolver shown in FIG. 1;

FIG. 4 is a cross-sectional view showing a rolling bearing apparatus according to another embodiment of the present invention;

FIG. 5 is a cross-sectional view showing a wheel-use rolling bearing apparatus according to still another embodiment of the present invention;

FIG. 6 is a perspective view taken along the line (6)-(6) in FIG. 5;

FIG. 7 is a schematic illustration showing a configuration of the brushless resolver shown in FIG. 5;

FIG. 8 is a cross-sectional view showing a wheel-use rolling bearing apparatus according to a further embodiment of the present invention;

FIG. 9 is a perspective view taken along the line (9)-(9) in FIG. 8;

FIG. 10 is a cross-sectional view showing a wheel-use rolling bearing apparatus according to a still further embodiment of the present invention;

FIG. 11 is a cross-sectional view showing a rolling bearing apparatus according to a yet further embodiment of the present invention;

FIG. 12 is a perspective view taken along the line (12)-(12) in FIG. 11;

FIG. 13 is a schematic illustration showing a configuration of the rolling bearing apparatus shown in FIG. 11;

FIG. 14 is a cross-sectional view showing a rolling bearing apparatus according to a yet further embodiment of the present invention;

FIG. 15 is a perspective view taken along the line (15)-(15) in FIG. 14;

FIG. 16 is a schematic illustration showing a configuration of the rolling bearing apparatus shown in FIG. 14;

FIG. 17 is a cross-sectional view showing a rolling bearing apparatus according to a yet further embodiment of the present invention; and

FIG. 18 is a cross-sectional view showing a rolling bearing apparatus according to a yet further embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

FIG. 1 to FIG. 3 show the best mode for carrying out the present invention. The rolling bearing apparatus comprises an inner ring 2 as a rolling element, an outer ring 3 as a non-rolling element, a plurality of balls 4 and a cage 5. The outer ring 3 is fitted to the inside openings of a housing (not shown) and the like to be a non-rolling element, and is disposed concentrically with the inner ring 2 on the outer periphery side. The balls 4 are housed inside a plurality of pockets provided in the cage 5 so as to be inserted in the circular space between the inner ring 2 and outer ring 3 at regular intervals on the circumference.

A brushless resolver 10 is a VR (variable reluctance) type and is installed to the rolling bearing apparatus as the rotation detector. The resolver 10 detects the rotation state (non-rotation state, rotation angle, rotation speed, rotation direction and the like) of the inner ring 2. The resolver 10 uses the inner ring 2 as a rotor. The resolver 10 comprises a stator 12, an exciting winding 13, and two output windings 14, 15. The resolver 10, for example, is a one-phase exciting/two-phase output type resolver. The inner ring 2 is made of a magnetic material. A flat portion 2 a is provided in a region on the circumference at a prescribed angle in the outer periphery shoulder of the inner ring 2 and other outer peripheral surface is in a circular shape. The outer periphery shoulder of the outer ring 2 may be in any shapes such as an oval, and a rice-ball shape as long as it is the shape which changes the gap permeance in between the outer peripheral surface of each tooth 12 a in accordance with the rotation. The rotor may be formed with a material different from that of the inner ring 2.

The stator 12 is made of a magnetic material and fixed by being press-fitted to the inner peripheral shoulder of the outer ring 3. The inner periphery of the stator 12 is in a comb shape. The exciting winding 13, the output windings 14, 15 are wound, as necessary, to the tooth 12 a provided in some areas on the circumference of the stator 12. A thin connecting part 12 b is provided in between each tooth 12 a as the magnetic paths. In FIG. 2, the number of the polar teeth 12 a provided is 8, however, in FIG. 3, the number is 4 for the conveniences' sake of presenting description. The minimum number of the polar teeth 12 a is 2, which are being shifted from one another by 90° in the circumferential direction, and when increasing the number, it should be the multiples of 2. The ball set bore diameter of the polar teeth 12 a of the stator 12 is set to be slightly larger than the diameter of the inner ring 2.

It is preferable that the rotor and the stator are made of a magnetic material with a small magnetic resistance and a high magnetic saturation density, e.g., a soft magnetic material. Specifically, there are a magnetic material containing iron as a main component and a magnetic material containing nickel as a main component. Examples are a laminated silicon steel plate or a single-layered silicon steel plate, permalloy (alloy of iron and nickel), ferrite, soft ferrite ceramic and the like. Needless to say, by using the material with a smaller reluctance as described above as the magnetic material for the rotor and the stator constituting such resolver, the change in the gap permeance between the rotor and the stator in accordance with the rotation of the rotor can be clearly detected. Thus, the precision of generating the induced voltage (rotation state detection voltage) of the winding according to the change is improved so that it is preferable for improving the accuracy of detecting the rotation state.

The exciting wiring 13 is wound in series to each tooth 12 a of the stator 12. The output windings 14, 15 are distributed-wound to each tooth 12 a so that each induced voltage distribution becomes a sine wave distribution. When the sine wave exciting voltage is inputted to the exciting winding 13, wave-shaped two-phase alternating voltage signals, which are electrically shifted from each other at 90°, are outputted from each of the output windings 14, 15. For example, when the sine wave exciting voltage is inputted to the exciting winding 13, a sine wave signal is outputted from the output winding 14 and a cosine wave signal which is shifted from the sine wave signal at 90° is outputted from the output winding 15.

In the resolver 10, when the inner ring 2 rotates under the state where one-phase alternate voltage is applied to the exciting winding 13, the gap permeance between the outer peripheral surface and the inner peripheral surface of each tooth 12 a of the stator 12 changes in order and each of the output windings 14, 15 outputs the sine wave and cosine wave signals whose amplitude change in accordance with the change in the gap permeance. The output signals are inputted to a signal processing circuit 20. When the inner ring 2 is at rest, the gap permeance between the outer peripheral surface and the inner peripheral surface of each tooth 12 a of the stator 12 does not change so that each of the output windings 14, 15 outputs the sine wave and cosine wave signals with almost constant amplitude.

The signal processing circuit 20 may be a known R/D (resolver/digital) converter and a DSP (digital signal processor), and performs recognition processing of the rotation state (stop position, rotation direction, rotation angle, rotation speed and the like) of the inner ring 2 through a known signal processing based on input signals.

As described above, it has a configuration in which the resolver 10 is mounted on the rolling bearing apparatus. Therefore, it is possible to successfully detect the non-rotation state where the inner ring 2 is at rest and also to detect the rotation state of the inner ring 2 with higher precision than that of the active-type rotation detector. The inner ring 2 also serves as the rotor of the resolver 10 so that the configuration is simplified and the cost can be reduced. The dimension of the inner peripheral surface of the outer ring 3 is adjusted with high precision by polishing and the like. Thus, the mounting accuracy of the resolver 10 is improved which contributes to the improvement in the accuracy of detecting the rotation by the resolver 10.

In the present invention, the resolver 10 is unified with the rolling bearing apparatus so that the resolver can work at its original characteristic and improve the accuracy of detecting the rotation state. For example, in an ordinal resolver, allowable value of the run-out precision (axial run-out precision) of the rotor and the stator in the radial direction is 50 μm or less and the allowable shift amount of the rotor and the stator in the axial direction is ×250 μm. In a deep groove ball bearing according to the embodiment, for example, when the precision is in a regular class and the nominal dimension of the inner diameter d of the inner ring is 10 mm to 80 mm, the run-out precision in the radial direction (radial inner clearance) is about 3 μm to 30 μm and the allowable shift amount in the axial direction (axial inner clearance) is 0 to 220 μm, which sufficiently meet the allowable precision for mounting the resolver. The above-described values are the precision of a single rolling bearing itself and when the rolling bearing is mounted between the housing and a spindle, the inner clearance becomes further reduced, thereby further improving the precision. Balls of the rolling bearing apparatus may be provided in double rows. The rolling bearing apparatus 1 maybe various ball bearings such as a roller bearing, a tapered roller bearing and the like.

ANOTHER EMBODIMENT

Another embodiment of the present invention will be described hereinafter.

As shown in FIG. 4, the rolling bearing apparatus is an angular ball bearing type and comprises an outer ring 3 as a non-rolling element, two inner rings 2A, 2B as rolling elements, a plurality of balls 4, two cages 5A, 5B, and two seals 6, 7. Two raceway grooves 3 a, 3 b are formed being separated away from each other in the inner peripheral surface of the outer ring 3 in an axial direction. The stator 12 of the resolver 10 is mounted between the two raceways 3 a, 3 b. The stator 12 is fixed by being press-fitted to the outer ring 3. The rotor 11 of the resolver 10 is disposed in the outer periphery of the area where the inner rings 2A, 2B face each other in the axial direction.

The rotor 11 comprises a flat portion 11 a in a prescribed angle range of the outer peripheral surface. A region 11 b which is a half-portion of the inner peripheral surface of the rotor 11 in the axial direction is fixed by being press-fitted to the inner end side of the first inner ring 2A in the axial direction and the inner diameter of the other half-portion of the region 11 c in the axial direction is set to be larger than that of the region 11 b. Thereby, the region 11 c becomes non-contact with the second inner ring 2B. The exciting winding 13 and the output windings 14, 15 are lead out to the outside through a through-hole 3 c provided in one area in the center on the circumference of the outer ring 3 in the axial direction.

As shown in FIG. 5 to FIG. 7, the rolling bearing apparatus is used for supporting the idler wheel of an automobile. The rolling bearing apparatus comprises a hub wheel 22 and a double row rolling bearing 23. A flange 22 a extending towards the outward-radial direction is formed in the outer peripheral surface of the hub wheel 22 closer to the one of the spindle end. The double row rolling bearing 23 is mounted outside on the outer peripheral surface on the inner side of the vehicle than the flange 22 a of the hub wheel 22. A nut spindle part 22 b with a small diameter is provided in an end of the hub wheel 22 on the vehicle inner side.

The double row rolling bearing 23 is a double row angular contact ball bearing with vertex of contact angles outside of bearing, and comprises a single outer ring 31 having double row raceway grooves, a single inner ring 32 having a single row raceway groove being mounted outside the small-diameter outer peripheral surface of the hub wheel 22, a plurality of balls 33 arranged in double rows, and two cup-type cages 34, 35. The large-diameter outer peripheral surface of the hub wheel 22 is the inner ring raceway surface of the ball groups 33 in one of the rows. A flange 36 extending towards the outward-radial direction is formed in the outer peripheral surface of the outer ring 31. The flange 36 is fixed to a carrier to be a part of a vehicle body or to a knuckle through a bolt. The disc rotor and the wheels of the disc brake gear are fixed by being pinched in between the outer side surface of the hub wheel 22 on the vehicle outer side of the flange 22 a and a nut being screw-fitted to bolts 25 which are through-fitted to several areas on the circumference of the flange 22 a.

The inner ring 32 is unified with the hub wheel 22 through a hexagonal nut 26 as a rolling element being screw-fitted to the screw spindle 22 b. Thereby, the hub wheel 22 becomes a rolling element and the outer ring 31 becomes a non-rolling element. A cap 27 is mounted on one end of the outer ring 31 on the vehicle inner side and seals the opening of the inner ring 31 on the vehicle inner side. A seal ring 28 is mounted on an end of the outer ring 31 on the outer side, forming a contact sealed area between with the outer peripheral surface of the hub wheel 22. Grease (not shown) is enclosed inside the opposing space between the outer ring 31 and the inner ring 32 formed by the cap 27 and the seal ring 28.

In the above-described rolling bearing apparatus, a VR-type resolver 10 as a rotation detector is mounted. The resolver 10 detects the rotation state (rotation stop state, rotation angle, rotation speed, rotation direction and the like) of the hub wheel 22. The resolver 10 comprises the stator 12, the exciting winding 13, the output windings 14, 15, and a hexagonal nut 26 which is a rolling element serving as the rotor. The resolver 10 is a one-phase exciting/two-phase output type.

The hexagonal nut 26 is made of a magnetic material and the outer peripheral surface is formed to be in the shape which changes the gap permeance between with the internal diameter face of the stator 12 in accordance with the rotation. It may be, in addition to the above-described shape, an oval, a rice-ball shape and the like. The rotor may be provided as a separate member without using the hexagonal nut 26 as the rotor.

The stator 12 is made of a magnetic material and fixed to the inner periphery of a cylindrical part 27 a of the cap 27 by press-fitting and the like. The inner periphery of the stator 12 is to be in a comb shape. The exciting winding 13 and the output windings 14, 15 are wound to the polar teeth 12 a provided in several areas of the stator 12. A thin connecting part 12 b is provided in between each tooth 12 a as a magnetic path.

The rolling bearing apparatus comprising the above-described configuration as shown in FIG. 5 to FIG. 7 can successfully detect by the resolver 10 the non-rolling state where the hub wheel 22 is at rest and also detect the rotation state of the hub wheel 22 with higher precision than that of the active-type rotation detector. Therefore, in a vehicle to which the bearing apparatus is mounted, the output of the resolver 10 can be used, for example, as the moving information such as a global positioning system (GPS) to extend the applicability. On the other hand, the hexagonal nut 26 is also used as the rotor of the resolver 10 so that the configuration can be simplified and the cost can be reduced.

In the case of the above-described rolling bearing apparatus, in general, it is used with a negative clearance by applying a preload. Thus, the shift amount in both the radial direction and the axial direction is “0”. Thereby, the allowable accuracy of mounting the resolver is sufficiently satisfied so that the accuracy of detecting the rotation state of the resolver can be improved. Also, in other types of the rolling bearing apparatuses such as a tapered roller bearing and a cylindrical roller bearing, the precision in the radial direction and the axial direction is excellently controlled so that the accuracy of detecting the rotation state of the resolver 10 can be improved.

The positional relation of the stator and the rotor may be reversed from the one described in each of the above-described embodiments, i.e., the stator may be disposed on the inner diameter side and the rotor is disposed on the outer diameter side. For example, as the rolling bearing apparatus, there is a case where the outer ring is rotatable and the inner ring is non-rotatable. In such a case, contrary to the above-described configuration, the rotor of a brushless resolver may be unified with the outer ring and the stator of the resolver may be mounted to the inner ring. As the rotation detector, other types of resolvers and brushless synchro may be used.

The hub wheel 22 and the inner ring 32 may be unified by, without using the hexagonal nut 26, making the end of the hub wheel 22 on the vehicle inner side be in a cylindrical shape and pressing the cylindrical part against the outer end face of the inner ring 32 after spreading it in the outward-radial direction through rolling caulking. In this case, the outside surface of the caulked part formed in the end part of the hub wheel 22 on the vehicle inner side may be formed in a shape to serve as the rotor of the resolver 10. Also, the rotor may be separately mounted on the outer periphery of the caulked part.

As shown in FIG. 8 and FIG. 9, the resolver 10 is disposed in the region between the double row raceway grooves 31 a, 31 b of the outer ring 31 as a non-rolling element in the axial direction. The stator 12 of the resolver 10 is mounted in the inner peripheral surface in the intermediate area of the outer ring 31 in the axial direction. Notches 22 c are provided in several areas on the circumference of the outer peripheral surface of the hub wheel 22 as the rolling element which opposes the stator 12. With the notches 22 c, the outer periphery surface of the hub wheel 22 becomes the rotor of the resolver 10. The stator 12 is fixed to the outer ring 31 by being press-fitted. The exciting winding 13 and the output windings 14, 15 are lead out to the outside from a through-hole provided in one area on the circumference in the center of the outer ring 31 in the axial direction. Although not shown in figure, the rotor of the resolver 10 may be mounted outside in a prescribed region of the hub wheel 22 as a separate element. The dimension of the inner peripheral surface of the outer ring 31 is adjusted with high precision by polishing and the like, which contributes to the improvement in the detection accuracy of the resolver 10.

As shown in FIG. 10, the circular diameter (PCD) connecting each of the ball group 33 on the vehicle outer side row is set to be larger than the PCD of the ball group 33 on the vehicle inner side. Specifically, the raceway groove 31 a on the vehicle outer side of the outer ring 31 is made to have a larger diameter than that of the raceway groove 31 b on the vehicle inner side, while the raceway groove 22 d of the hub wheel 22 is made to have a larger diameter than that of the raceway groove 32 a of the inner ring 32. Thereby, the region of the outer ring 31 to which the resolver 10 is mounted is made to have a large diameter. In this case, due to a flange 31 c facing the inward-radial direction provided between the mounting region of the resolver 10 in the outer ring 31 and the raceway groove 31 b, displacement of the resolver 10 towards the vehicle inner side can be successfully restricted. In the above-described rolling bearing apparatus, the hub wheel 22 is made to be in a hollow shape and a driving shaft is spline-fitted to the center hole of the hub wheel 22 so as to prepare a drive wheel type.

The type of the above-described bearing apparatus may be various kinds of mitred type double row rolling bearings such as a tapered roller and the like. Provided that it is a mitred type double row ball bearing, the relative positions of the rotor and the stator of the resolver 10 can be maintained with high precision so that the accuracy of detecting the rotation state of the resolver 10 can be improved. Also, in other types of rolling bearing such as the tapered roller bearing, cylindrical roller bearing and the like, the precision in the radial direction and the axial direction is controlled with high precision so that the accuracy of detecting the rotation state of the resolver 10 can be improved.

As shown in FIG. 11 to FIG. 13, the rolling bearing apparatus comprises the inner ring 2, the outer ring 3, a plurality of balls 4, and a cage 5. These are the same as the one shown in FIG. 1. The resolver 10 and an AC generator 40 are installed to the rolling bearing apparatus.

The exciting winding 13 of the resolver 10 is wound in series to the tooth 12 a of the stator 12. The output windings 14, 15 are distributed-wound to each tooth 12 a so that each induced voltage distribution becomes a sine wave distribution. When the sine wave exciting voltage is inputted to the exciting winding 13, two-phase alternating voltage signals, which are electrically shifted from each other at 90°, are outputted from each of the output windings 14, 15. For example, when the sine wave exciting voltage is inputted to the exciting winding 13, a sine wave signal is outputted from the output winding 14 and a cosine wave signal which is shifted from the sine wave signal at 90° is outputted from the output winding 15.

The AC generator 40 generates a sine wave voltage in accordance with the rotation of the inner ring 2 and applies the voltage as an input exciting voltage to the resolver 10. The AC generator 40 comprises a generating rotor 41 being unified on the inner ring 2 side and a generating stator 42 being unified on the outer ring 3 side. The generating rotor 41 comprises a bracket 43 mounted to the inner ring 2 on the outer side of the resolver 10, an iron core 44 mounted to the bracket 43, and a circular magnet 45 having magnetic poles with different polarities being alternately disposed in the circumferential direction, which is mounted to the iron core 44 with only the outer side being exposed. The generating stator 42 comprises a bracket 46 mounted to the outer ring 3 on the outer side of the resolver 10, an iron core 47 mounted to the bracket 46, and a generating coil 48 wound to the iron core 47 with only the inner side being exposed.

Now, the operation will be described. When the inner ring 2 rotates, the AC generator 40 generates a sine wave voltage. The sine wave voltage generated in the AC generator 40 is applied as one-phase alternating voltage (input exciting voltage) to the exciting winding 13 of the resolver 10. On the other hand, in accordance with the rotation of the inner ring 2, the gap permeance between the outer peripheral surface of the inner ring 2 and each tooth 12 a of the detection stator 12 of the resolver 10 change and signals whose amplitudes change without phase are outputted from the output windings 14, 15 of the resolver 10. These signals are inputted to the signal processing unit 2 through a signal wire (not shown).

The AC generator 40 is mounted onto the above-described rolling bearing apparatus so that it becomes unnecessary to provide an exciting voltage inputting device on the outside and also unnecessary to connect the resolver 10 to the exciting voltage inputting device through the signal wire. Further, the resolver 10 and the AC generator 40 are closely disposed so that it becomes easy to electrically connect the resolver 10 to the AC generator 40 and the cost of equipment can be reduced.

As shown in FIG. 14 to FIG. 16, the rolling bearing apparatus is further provided with a radio transmitter 60. The radio transmitter 60 radio-transmits the output signals of the resolver 10 to the signal processing unit 20 by radio waves, infrared rays, ultrasonic waves and the like. The signal processing unit 20 comprises a receiver unit 20 a for receiving the transmitted signals from the radio transmitter 60. The radio transmitter 60 may be the one which performs transmission by magnetic coupling. In the case of using this transmission type, it may be formed using transmission coils which excites by a given frequency and a receiver coil generating a voltage by electromagnetic induction may be provided in the signal processing unit 20 as the receiver unit. The radio transmitter 60 is mounted to be unified on the outer side of the bracket 46 on the generating stator 42 side of the AC generator 40.

With the configuration described above, when the inner ring 2 rotates, the AC generator 40 generates a sine wave voltage. The sine wave voltage generated in the AC generator 40 is applied as one-phase alternating voltage (input exciting voltage) to the exciting winding 13 of the resolver 10 and also is supplied to the radio transmitter 60 as the driving voltage. On the other hand, in accordance with the rotation of the inner ring 2, the gap permeance between the outer peripheral surface of the inner ring 2 and each tooth 12 a of the detection stator 12 of the resolver 10 change and signals whose amplitudes change without phase are outputted from the output windings 14, 15 of the resolver 10. The signals are inputted to the receiver unit 20 a of the signal processing unit 20 through the radio transmitter 20. The signal processing unit 20 recognizes the rotation state (rotation direction, rotation angle, rotation speed and the like) of the inner ring 2 based on the signals received in the receiver unit 20 a.

As described above, in the above-described rolling bearing apparatus, it becomes possible to detect the rotation state of the inner ring 2 with higher precision than that of the conventional active type rotation detector. Further, the inner ring 2 is also used as the detection rotor of the resolver 10 so that the configuration can be simplified and the cost can be reduced. Furthermore, the dimension of the inner peripheral surface of the outer ring 3 is adjusted with high precision by polishing and the like. Thus, the precision of mounting the resolver 10 can be improved, which contributes to the improvement in the detection accuracy of the resolver 10.

Further, the resolver 10, the radio transmitter 60 and the AC generator 40 are closely disposed so that it becomes easy to connect electrically connect the resolver 10, the radio transmitter 60 and the AC generator 40, respectively, and the cost of equipment can be reduced.

As shown in FIG. 17, the rolling bearing apparatus has a double row ball bearing structure to which the resolver 10 and the AC generator 40 are installed. The resolver 10 is provided in the inner peripheral surface between two raceway grooves of the outer ring 31. The AC generator 40 is provided inside the cap 27. Specifically, the stator 12 of the resolver 10 is installed in the inner peripheral region in the intermediate area of the outer ring 31 as the rolling element in the axial direction and the hub wheel 22 as the rolling element is also used as the rotor of the resolver 10. In other words, the flat portion 22 a is provided in the region of the outer peripheral surface of the hub wheel 22, which opposes the stator 12 in the radial direction and the hub wheel 22 whose outer peripheral surface is made to have a different diameter due to the flat portion 22 c is used as the detection rotor. The generating stator 42 of the AC generator 40 is fixed by being fitted to the inner peripheral surface of the cylindrical part 27 a of the cap 27 through a non-magnetic material 29. The generating rotor 41 of the AC generator 40 is fixed to the outer periphery of the hexagonal nut as the rolling element which connects the hub wheel 22 and the inner ring 32 on the vehicle inner side of the hub wheel 22. In the rolling bearing apparatus, the operation of the resolver 10 and the AC generator 40 are basically the same as the ones described above.

In the embodiment, in addition to the one in which the circular diameters (PCD) connecting the centers of the balls 33 in each row are the same, the present invention can be broadly applied to various known types of wheel-use rolling bearing apparatus. Further, a radio transmitter can be installed to the rolling bearing apparatus. In this case, the radio transmitter can be mounted, for example, to a prescribed region on the circumference of the outer peripheral surface of the cylindrical part of the cap. The operation in this case is basically the same as the above-described embodiments.

As shown in FIG. 18, the resolver 10, the radio transmitter 60 and the AC generator 40 are installed to the rolling bearing apparatus, while the signal processing unit 20 is provided in the outer peripheral surface of the cap 27. The resolver 10 is provided in the inner peripheral region between two raceway grooves of the outer ring 31 and the radio transmitter 60 is mounted in the outer peripheral surface of the cylindrical part 27 a of the cap 27. Further, the AC generator 40 is provided inside the cap 27. Specifically, the stator 12 of the resolver 10 is mounted in the inner peripheral region in the intermediate area of the outer ring 31 in the axial direction and the hub wheel 22 is also used as the rotor of the resolver 10. That is, the flat portion 22 a is provided in the region of the outer peripheral surface of the hub wheel 22, which opposes the stator 12 in the radial direction and the hub wheel 22 whose outer peripheral surface is made to have a different diameter due to the flat portion 22 c is used as the detection rotor. The generating stator 42 of the AC generator 40 is fixed by being fitted to the inner peripheral surface of the cylindrical part of the cap 27 through a non-magnetic material 29. The generating rotor 41 of the AC generator 40 is fixed to the outer periphery of the hexagonal nut as the rolling element which connects the hub wheel 22 to the inner ring 32 on the vehicle inner side of the hub wheel 22. In the embodiment, the operation of the resolver 10, the radio transmitter 60 and the AC generator 40 are also basically the same as the ones described above.

The positional relation of the stator 12 and the detection rotor of the resolver 10 may be reversed from the one described above, i.e., the stator 12 may be disposed on the inner side and the rotor is disposed on the outer side. For example, as the above-described rolling bearing apparatus, there may be a case where the outer ring 32 is made rotatable and the inner ring 32 is made non-rotatable. In this case, the rotor of the resolver 10 may be mounted to be unified with the outer ring 31 and the stator 12 of the resolver 10 may be mounted to the inner ring 32 as the non-rolling element.

INDUSTRIAL APPLICABILITY

The present invention can be used as a detection apparatus for detecting the rotation state in a vehicle such as an automobile. 

1. A rolling bearing apparatus, comprising a rolling element; a non-rolling element disposed concentrically with said rolling element; and a rotation detector for outputting an input exciting voltage by converting it to an induced voltage according to a relative rolling state of said rolling element and said non-rolling element.
 2. The rolling bearing apparatus according to claim 1, wherein said rotation detector comprises: a rotor provided in said rolling element; a stator provided in said non-rolling element; and an exciting winding and output windings wound to said stator, wherein said output windings induce a voltage according to a gap permeance between said rotor and said stator in response to said exciting voltage inputted to said exciting winding.
 3. The rolling bearing apparatus according to claim 2, wherein said stator is formed with a plurality of polar teeth provided in a surface of said non-rolling element which opposes said rolling element in a circumferential direction while said exciting winding and output windings are wound to each polar tooth of said stator, and said rotor comprises a flat portion formed on a circumference of the surface in said rolling element which opposes said plurality of polar teeth provided in said non-rolling element.
 4. The rolling bearing apparatus according to claim 2, wherein: said rolling element is an inner ring; said rotor is formed by an outer peripheral shoulder of said inner ring; and a flat portion is formed on a circumference of said outer peripheral shoulder.
 5. The rolling bearing apparatus according to claim 2, wherein: said rolling element is made up of two inner rings disposed adjacent to each other in an axial direction; said rotor is provided in an outer peripheral surface of areas of said two inner rings, which face each other in the axial direction; said non-rolling element is an outer ring being disposed concentrically with said two inner rings in an outward-radial direction, while having two raceway grooves in an inner peripheral surface being separated away from each other in an axial direction by opposing each raceway groove of said two inner rings; and said stator is provided in a region between both raceway grooves of said outer ring.
 6. The rolling bearing apparatus according to claim 5, wherein: said rotor is fixed by fitting a half-portion of an inner peripheral surface of said rotor in an axial direction into one inner end side in an axial direction of one of said inner rings; and a single bore diameter of other half-portion of in the axial direction is made larger than said half-portion in the axial direction so that said other half-portion becomes non-contact with other inner ring.
 7. The rolling bearing apparatus according to claim 5, wherein said exciting winding and said output windings are lead out from a through-hole provided in an area on a center of a circumference of said outer ring in an axial direction.
 8. The rolling bearing apparatus according to claim 2, wherein said rolling element comprises: a hub wheel; inner rings fitted in an outer periphery of said hub wheel; and a nut mounted on one end side of said hub wheel in an axial direction for connecting said inner rings to said hub wheel, wherein said nut serves as said rotor.
 9. The rolling bearing apparatus according to claim 2, wherein said rolling element comprises: a hub wheel with a flange provided in an outer periphery closer to an end of one spindle in an outward-radial direction while having an outer peripheral surface with a small diameter in an outer peripheral surface on an end of vehicle inner side; an inner ring mounted outside the small-diameter outer peripheral surface of said hub wheel; a nut spindle portion formed on the vehicle inner end of said hub wheel; and a nut being helically mounted on said nut spindle portion, said rotor is formed of said nut; said non-rolling element is an outer ring disposed on an outer periphery side of said hub wheel; a cap is mounted in a vehicle inner side opening of said outer ring; and said stator is fixed to an inner periphery of said cap and said stator opposes said nut in a radial direction.
 10. The rolling bearing apparatus according to claim 2, wherein said rolling element comprises: a hub wheel with a flange provided in an outer periphery closer to an end of one spindle in an outward-radial direction while having outer peripheral surfaces with a large diameter and a small diameter in an outer peripheral surface on an end of said vehicle inner side; and inner rings mounted outside the small-diameter outer peripheral surface of said hub wheel; said non-rolling element is an outer ring disposed on an outer periphery of said hub wheel; said stator is mounted in a center region of an inner peripheral surface of said outer ring in an axial direction; and said rotor is formed by notches provided in a plurality of areas on an circumference of a large-diameter outer peripheral surface with a large diameter of said hub wheel, which opposes said stator in a radial direction.
 11. The rolling bearing apparatus according to claim 2, wherein said rolling element comprises: a hub wheel with a flange provided in an outer periphery closer to an end of one spindle in an outward-radial direction while having outer peripheral surfaces with a large diameter and a small diameter in an outer peripheral surface on an end of said vehicle inner side and having an inner ring raceway groove in said large-diameter outer peripheral surface; inner rings mounted outside said small-diameter outer peripheral surface of said hub wheel; said non-rolling element is an outer ring disposed concentrically with said two inner rings in an outward-radial direction while having two raceway grooves in an inner peripheral surface being separated away from each other in an axial direction opposing each raceway groove of said two inner rings; a vehicle outer-side raceway groove of said outer ring is made to have a larger diameter than that of a vehicle inner-side raceway groove, the inner ring raceway groove of said hub wheel is made to have a larger diameter than that of the raceway groove of said inner ring, and PCD of said vehicle outer side ball group, among two groups of the vehicle inner side and vehicle outer side mounted in between said each raceway groove, is made to have a larger diameter than that of PCD of a vehicle inner side ball group; said stator is mounted in a canter region of an inner peripheral surface of said outer ring in an axial direction; and said rotor is formed by notches provided in a plurality of areas on an circumference of an outer peripheral surface region in an outer peripheral surface of said hub wheel, which opposes said stator in a radial direction.
 12. The rolling bearing apparatus according to claim 1, further comprising a generator for generating a voltage in accordance with rotation of said rolling element and inputting the voltage as an input exciting voltage to said rotation detector.
 13. The rolling bearing apparatus according to claim 12, wherein said generator comprises: a generating rotor provided in said rolling element by disposing magnetic poles with different polarities alternately in a circumferential direction; and a generating stator provided in said non-rolling element, which has an electric coil opposing the magnetic poles of said generating rotor in an radial direction.
 14. The rolling bearing apparatus according to claim 1, further comprising a radio transmitter for radio-transmitting signals outputted from said rotation detector to a signal processing unit provided outside.
 15. The rolling bearing apparatus according to claim 14, further comprising a generator for generating a voltage in accordance with rotation of said rolling element and inputting the voltage as an input exciting voltage to said rotation detector while supplying it as a driving voltage to said radio transmitter.
 16. The rolling bearing apparatus according to claim 1, further comprising a signal processing unit for processing output signals from said rotation detector.
 17. The rolling bearing apparatus according to claim 12, further comprising a signal processing output from said generator.
 18. The rolling bearing apparatus according to claim 14, further comprising a signal processing output signals from said radio transmitter.
 19. The rolling bearing apparatus according to claim 1, wherein said rotation detector comprises a rotor provided in said rolling element, a stator provided in said non-rolling element, an exciting winding and output windings wound to said stator, and further comprises a resolver which induces a voltage according to a gap permeance between said rotor and said stator in response to an exciting voltage inputted to said exciting winding from said output windings. 